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Editorial

Plant research projects are increasingly producing large systematic collections of phenotype data. But how can it be stored so that others can easily use it and that proper credit goes to the creators of the data?

Increasing the yields of crops requires the investigation, and subsequent exploitation, of the genetic diversity preserved beyond the narrow range of commonly cultivated varieties. Such an undertaking requires a partnership of academia and industry.

News and Views

Animal microRNAs appear to either cleave or repress the translation of target messenger RNAs depending on complementarity between the two. Contrastingly, the biogenesis of plant microRNAs seems to dictate their mode of action.

The auxin receptor TIR1 is an F-box protein functioning in a ubiquitin ligase complex to target repressors for degradation. It is itself an unstable protein, but newly identified mutations protect both TIR1 and its substrates
from degradation. These mutations could help in identifying the substrates for hundreds of other F-box proteins.

The nitrate transporter NRT1.1 is a versatile plasma-membrane protein that mediates not only nitrate uptake in roots, but also nitrate sensing and signalling. A study of the structural features of NRT1.1 reveals how this protein can coordinate a range of physiological and morphological responses to nitrate.

Reviews

The protein content of plant cells is constantly being updated. Proteomic analyses are revealing the cellular processes that contribute to protein synthesis and degradation in plants, and their sensitivity to developmental and environmental change.

In Arabidopsis the plasma membrane nitrate transceptor (transporter/receptor) NRT1.1 governs many physiological and developmental responses to nitrate. Point mutations in two key residues of the transceptor differentially affect several of the NRT1.1-dependent responses to nitrate, suggesting that NRT1.1 activates independent signalling pathways.

Touch can lead to a reduction in plant growth and a delay in flowering time. Experiments with wild-type Arabidopsis plants, and mutants impaired in gibberellin signalling and breakdown, suggest that touch-induced changes in plant morphology depend on gibberellin catabolism.

Little is known about the selection of regulatory mechanisms for plant microRNAs. Now a Dicer partnering protein, DRB2, is reported to determine translational inhibition and repress transcript cleavage, allowing the selection of the two mechanisms.

The plant auxin receptor TIR1 needs to associate with the SCF complex to be functional and target substrates. Newly discovered mutations that can block this interaction suggest that TIR1 is autocatalytically degraded once assembled in the SCF complex.